Main periods of soil formation and sedimentation in forest-steppe landscapes of the Selenga midland during the Late Glacial and Holocene
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- 作者:Yu. V. Ryzhov ; V. A. Golubtsov ; D. V. Kobylkin…
- 关键词:landscape ; climatic changes ; soils ; paleosols ; Holocene ; Late Glacial ; Selenga midland ; Western Transbaikalia
- 刊名:Geography and Natural Resources
- 出版年:2015
- 出版时间:July 2015
- 年:2015
- 卷:36
- 期:3
- 页码:278-288
- 全文大小:6,226 KB
- 参考文献:1.Khotinskiy, N.A., The Holocene of Northern Eurasia, Moscow: Nauka, 1977 [in Russian].
2.Borisova, O.K., Landscape-Climatic Changes During the Holocene, Izv. RAN, Seriya Geogr., 2014, n. 2, pp. 5鈥?0 [in Russian].
3.Dynamics of Landscape Complexes and Inland Sea Basins of Northern Eurasia for the Last 130 000 Years. Development of Landscapes and Climate of Northern Eurasia. The Late Pleistocene鈥揌olocene鈥揊orecast Elements: Atlas-Monograph, Issue 2: General Paleogeography, A.A. Velichko, Ed., Moscow: GEOS [in Russian].
4. Global and Regional Changes of Climate and Natural Environment During the Late Cainozoic in Siberia, A.P. Derevyanko, Ed., Novosibirsk: Izd-vo SO RAN, 2008 [in Russian].
5.Bradley, R.S., Past Global Changes and Their Significance for the Future, Quaternary Science Reviews, 2000, vol. 19, pp. 391鈥?02.CrossRef
6.Karabanov, E.B., Prokopenko, A.A., Williams, D.F., and Khursevich, G.K., A New Record of Holocene Climate Change From the Bottom Sediments of Lake Baikal, Palaeogeography, Palaeoclimatology, Palaeoecology, 2000, vol. 156 (3鈥?), pp. 211鈥?24.CrossRef
7.Demske, D., Heumann, G., Granoszewski, W., Nita, M., Mamakowa, K., Tarasov, P.E., and Oberhansli, H., Late Glacial and Holocene Vegetation and Regional Climate Variability Evidenced in High-Resolution Pollen Records From Lake Baikal, Global and Planetary Change, 2005, vol. 46 (1鈥?), pp. 275鈥?79.CrossRef
8.Tarasov, P.E., Bezrukova, E.V. and Krivonogov, S.K., Late Glacial and Holocene Changes in Vegetation Cover and Climate in Southern Siberia Derived From a 15 kyr Long Pollen Record From Lake Kotokel, Climate of the Past, 2009, vol. 5, pp. 285鈥?95.CrossRef
9.Bezrukova, E.V., Tarasov, P.E., Kulagina, N.V., Abzaeva, A.A., Letunova, P.P., and Kostrova, S.S., Palynological Study of Lake Kokotel鈥?Bottom Sediments (Lake Baikal Region), Russ. Geol. Geophys., 2011, vol. 52, issue 4, pp. 458鈥?65.CrossRef
10.Bezrukova, E.V., Krivonogov, S.K., Abzaeva, A.A., Vershinin, K.E., Letunova, P.P., Orlova, L.A., Takahara, H., Mieshi, N., Nakamura, T., Krapivina, S.M., and Kawamuro, K., Landscapes and Climate of Cisbaikalia in the Late Glacial and Holocene From Results of Comprehensive Investigations of Peat Bogs, Geologiya i Geofizika, 2005, vol. 46, no. 1, pp. 21鈥?3 [in Russian].
11.Dan鈥檏o, L.V., Bezrukova, E.V. and Orlova, L.A., Reconstructing the Development of the Geosystems of the Primorsky Range During the Latter Half of the Holocene, Geogr. Prir. Resur., 2009, no. 3, pp. 48鈥?5 [in Russian].
12.Birkeland, P.W., Soils and Geomorphology, New York: Oxford Univ. Press, 1999.
13.Sheldon, N.D. and Tabor, N.J., Quantitative Paleoenvironmental and Paleoclimatic Reconstruction Using Paleosols, Earth-Science Reviews, 2009, vol. 95 (1鈥?), pp. 1鈥?2.CrossRef
14.Zykina, V.S. and Zykin, V.S., Loess-Soil Sequence and Evolution of Natural Environment and Climate of Western Siberia in the Pleistocene, Novosibirsk: Geo, 2012 [in Russian].
15.Dan鈥檏o, L.V., The Evolution of Soils in the Taiga-Steppe Ecotone of the Baikal Region During the Holocene, Geogr. Prir. Resur., 2009, no. 4, pp. 17鈥?5 [in Russian].
16.Sycheva, S.A., Morpholithopedogenesis in Accumulative and Trans-accumulative Landscapes as a Special Mechanism of Soil-Lithogenic Memory, in Memory of Soils: Soil as Memory of Biosphere-Geosphere-Anthroposphere Interactions, Moscow: Izd-vo LKI, 2008, pp. 128鈥?61 [in Russian].
17.Retallack, G.J., Soils of the Past. An Introduction to Paleopedology, Oxford: Blackwell Science, 2001.
18. Handbook on the USSR Climate, Issue 23: Buryat ASSR and Chita Oblast, Partt 4: Air Humidity, Atmospheric Precipitation, Snow Cover, Leningrad: Gidrometeoizdat, 1968 [in Russian].
19.Bazarov, D.-D., Quaternary Deposits and Main Stages of Morphogenesis of the Selenga Middle Mountains, Ulan-Ude: Buryat. Kn. Izd-vo, 1968 [in Russian].
20.Reimkhe, V.V., Erosion Processes in Forest-Steppe Landscapes of Transbaikalia (Exemplified by the Kuitunka River), Novosibirsk: Nauka, 1986 [in Russian].
21.Vadyunina, A.F. and Korchagina, Z.A., Methods for Determining the Physical Properties of Soils and Earth Materials, Moscow: Vyssh. Shk., 1961 [in Russian].
22.Arinushkina, E.V., Manual on Chemical Analysis of Soils, Moscow: Izd-vo Mosk. Univer., 1970, pp. 166鈥?67 [in Russian].
23.Kononova, M.M., Organic Matter of Soils, Moscow: Izd-vo ANSSSR, 1963 [in Russian].
24.Bolonev, F.F., Semeiskie: Historical-Geographical Essays, Ulan-Ude: Buryat. Kn. Izd-vo, 1992 [in Russian].
25.Tonkonogov, V.D., Lebedeva, I.I. and Gerasimova, M.I., The Main Horizontal-Profile-Forming Processes in Soils of Russia, in Soil Formation Processes in Soils of Russia, Moscow: Izd-vo Pochv. Instituta im. V.V. Dokuchaeva, 2006, pp. 13鈥?7 [in Russian].
26.Aleksandrovskii, A.L. and Aleksandrovskaya, E.I., Soil Evolution and Geographical Environment, Moscow: Nauka, 2005 [in Russian].
27.Pigareva, N.N., Korsunova, T.M. and Pyankova, N.A., Specific Features of the Humus Status in Soils of Buryatia, Eurasian Soil Sci., 2008, vol. 41, issue 4, pp. 386鈥?93.CrossRef
28.Michelutti, N., Douglas, M.S.V., Wolfe, A.P., and Smol, J.P., Heightened Sensitivity of a Poorly Buffered High Arctic Lake to Late-Holocene Climatic Change, Quaternary Research, 2006, vol. 65, pp. 421鈥?30.CrossRef
29.Velichko, A.A., Andreev, A.A. and Klimanov, V.A., Climate and Vegetation Dynamics in the Tundra and Forest Zone During the Late Glacial and Holocene, Quaternary International, 1997, vol. 41/42, pp. 71鈥?6.CrossRef
30.Bezrukova, E.V., Belov, A.V., Abzaeva, A.A., Letunova, P.P., Sokolova, L.P., Kulagina, N.V., Fisher, E.E., First Detailed Datings of Record of Vegetation and Climate Changes in Northern Cisbaikalia During the Mid- and Late Holocene, Dokl. RAN, 2006, vol. 411, no. 2, pp. 254鈥?58 [in Russian].
31.Lehmkuhl, F., Hilgers, A., Fries, S., H眉lle, D., Schl眉tz, F., Shumilovskikh, L., Felauer, T., and Protze, J., Holocene Geomorphological Processes and Soil Development as Indicator for Environmental Change Around Karakorum, Upper Orkhon Valley (Central Mongolia), Catena, 2011, vol. 87, pp. 31鈥?4.
32.Lehmkuhl, F., H眉lle, D. and Knippertz, M., Holocene Geomorphic Processes and Landscape Evolution in the Lower Reaches of the Orkhon River (Northern Mongolia), Catena, 2012, vol. 98, pp. 17鈥?8.CrossRef
33.Chen, F., Yu, Z., Yang M., Ito E., Wang S., Madsen D.B., Huang X., Zhao Y., Sato T., Birks H.J.B., Boomer, I., Chen, J., An, C., and W眉nnemann, B., Holocene Moisture Evolution in Arid Central Asia and Its Out-of-phase Relationship With Asian Monsoon History, Quaternary Science Reviews, 2008, vol. 27, pp. 351鈥?64.CrossRef
34.Reshetova, S.A., Bezrukova, E.V., Panizzo, V., Henderson, A., Dar鈥檌n, A.V., and Kalugin A.V., Vegetation of Central Transbaikalia in the Late Glacial Period and Holocene, Geogr. Prir. Resur., 2012, no. 2, pp. 110鈥?17 [in Russian].
35.Vorobyeva, G.A., Soil as a Record of Natural Events of Cisbaikalia: The Problems of Soil Evolution and Classification, Irkutsk: Izd-vo Irk. Univer., 2010 [in Russian].
36.Tarasov, P., Bezrukova, E., Karabanov, E., Nakagawa, T., Wagner, M., Kulagina, N., Letunova, P., Abzaeva, A., Cranoszewski, W., and Riedel, F., Vegetation and Climate Dynamics During the Holocene and Eemian Interglacials Derived From Lake Baikal Pollen Records, Palaeogeography, Palaeoclimatology & Palaeoecology, 2007, vol. 252, pp. 440鈥?57.CrossRef
37.Chebykin, E.P., Erdington, D.N., Grachev, M.A., Zheleznyakova, T.O., Vorobyova, S.S., Kulikova, N.S., Azarova, I.N., Khlystov, O.M., and Goldberg, E.L., Abrupt Increase in Precipitation and Weathering of Soil in East Siberia Coincident With End of the Last Glaciations (15 cal. kyr BP), Earth and Planetary Science Letters, 2002, vol. 200, pp. 167鈥?75.CrossRef
38.Severinghaus, J.P. and Brook, E.J., Abrupt climate Change at the End of the Last Glacial Period Inferred from Trapped Air in Polar Ice, Science, 1999, vol. 286, no. 5441, pp. 930鈥?34.CrossRef
39.Feng, Z.D., Zhai, X.W., Ma, Y.Z., Huang, C.Q., Wang, W.G., Zhang, H.C., Khosbayar, P., Narantsetseg, T., Liu, K.B., and Rutter, N.W., Eolian Environmental Changes in the Northern Mongolian Plateau During the Past 35,000 yr, Palaeogeography, Palaeoclimatology, Palaeoecology, 2007, vol. 245, pp. 505鈥?17.CrossRef
40.Ryzhov, Yu.V., Chronology o Erosion-Accumulation Processes in Gully-Draw Systems of Southwestern Cisbaikalia in the Holocene, Geogr. Nat. Resour., 2012, vol. 33, issue 2, pp. 319鈥?26.CrossRef
41.Kolomiets, V.L. and Budaev, R.Ts., The Latest Data on the Age of Buried Soils Indicators of Changes in the Natural-Climatic situation During the Holocene of Southeastern Cisbaikalia and Western Transbaikalia, in Regional Response of Environment to Global Changes in Northeastern and Central Asia, Irkutsk: Izd-vo Instituta Geografii SORAN, 2012, vol. 2, pp. 34鈥?6 [in Russian]. - 作者单位:Yu. V. Ryzhov (1)
V. A. Golubtsov (1)
D. V. Kobylkin (1)
V. N. Chernykh (2)
1. Institute of Geography, Siberian Branch, Russian Academy of Sciences, Irkutsk, Russia
2. Buryat State University, Ulan-Ude, Russia - 刊物主题:Economic Geography; Landscape/Regional and Urban Planning;
- 出版者:MAIK Nauka/Interperiodica
- ISSN:1875-371X
文摘
On the basis of a comprehensive study of soil-sedimentary sequences, we reconstructed the history of soils and landscapes development in the central part of the Selenga midland (Kuitunka river basin). For the Late Glacial and Holocene four stages of deposition and soil formation have been identified: Late Glacial (15.0-11.7 kyr BP), Early- (11.7-8.8 kyr BP), Mid- (8.8-4.7 kyr BP), and Mid-Late Holocene (4.7-0 kyr BP). The Late Glacial period is characterized by short-lasting and contrasting climatic changes, leading to frequent successions of the phases of activation of erosion-accumulation processes and soil formation. We identified three phases of pedogenesis and the corresponding stages of climate warming and humidification (14.5-14.1; 14.0-13.3, and 13.0-12.6 kyr BP). Intensification of exogenous processes occurred in the time intervals 15.0-14.5; 14.1-14.0; 13.3-13.0, and 12.6-11.7 kyr BP. During the Early Holocene period the most optimal conditions for soil formation take place in the first half of the Preboreal (11.7-11.0 kyr BP). Later, there occurred an enhancement in climate aridization whose evidence manifests itself as high-carbonate aeolian-colluvial deposits. Pedogenesis in the second half of the Preboreal (11.0-10.5 kyr BP) and during the Boreal period (10.5-8.8 kyr BP) was proceeding in steppe/forest-steppe conditions under warmer and less humid climate in comparison with soils formed in the Late Glacial and first half of Preboreal. The Mid-Holocene and the Mid-Late Holocene periods were distinguished by relatively stable landscape-climatic conditions, implying formation of well-developed soils and stabilization of erosion-accumulation landforms. Two long-lasting intervals of intense pedogenesis (8.8-6.9, and 4.7-0 kyr BP) can be identified. Soil formation was proceeding under steppe vegetation in rather warm and slight moistening climatic conditions. From the Atlantic to the Subatlantic climate became more arid. Activisation of exogenous processes occurred in interval 6.9-4.7 kyr BP. Keywords landscape-climatic changes soils paleosols Holocene Late Glacial Selenga midland Western Transbaikalia